Humic Acid
It is theorised that Leonardite shale
originated from trees and other vegetation, which grew during the carboniferous
period when most of North America was a tropical type forest. Over the ages,
the vegetation underwent compaction and heating, slowly carbonising and forming
coal. Through this compaction, organic acids and esters present in the
vegetation were squeezed out, forming a pool on top of the lignite bed. This
pool dried, aged, and eventually formed Leonardite shale. The vegetative origin
of the Leonardite shale indicates this material is humus and contains Humic
Acids. The content of Humic Acids within the Leonardite shale is variable with
the location of deposits found throughout the world. Those deposits in the
North Dakota area are among the most pure in the world containing 80 to 90
percent Humic Acids. Any one of the other sources of Humic Acids, including
pear, muck, green, or animal manures, can be beneficial to plant growth when
incorporated into the soil. Leonardite shale is an easily available and
concentrated form of Humic Acids, making it the subject of much research work
and commercial use.
Humic acid is made up of three different compounds, organic matter, humus, and
humic substances. Organic matter is the plant and animal residue in the soil
at various stages of decomposition. Humus is the end product of microbial
degradation. Humic substances are naturally occurring organic materials with
high molecular weights that are not easily degraded. The importance of humus,
humic acids, and humates has long been recognised, but neither fully understood
nor appreciated.
Soil organic matter is plant and animal residues in the soil at various stages
of decomposition. Tissue is both the primary source of food for soil microorganisms
during decomposition, and the primary source of soil organic matter. When
plant tissue is added to the soil three basic actions take place. First, the
bulk of the material is converted to carbon dioxide, water, and energy through
enzymatic oxidation. Second, elements such as nitrogen, phosphorous and
sulphur are either released or immobilised in separate reactions. Third,
microbial resistive compounds are formed through modification of compounds in
the original plant tissue, or by microbial synthesis. During the enzymatic
changes of soil organic matter, simple products, such as carbon dioxide and
water, appear immediately. Other products, such as nitrate nitrogen, appear
only after the initial peak of vigorous activity has subsided.
Humus is the end product of the microbial decay of organic matter. Humus
contains both humic and non-humic material. Humus is relatively stable and
fairly resistant to further rapid breakdown. Humus is a tremendous food source
for soil microflora. Components of humus are oxidized or mineralised and then
utilised by plants. Humus is now known to include a broad spectrum of organic
constituents, many of which have their counterparts in biological tissues. It
is theorised that humus contains most, if not all, of the biological compounds
synthesised by living organisms, including plants.
Humic substances are yellow to black naturally occurring organic substances
with high molecular weights. Humic Acids (plural) is the collective name for
the acid radicals found in humic matter. Humic acid (singular) is the fraction
of humic substances insoluble in acidic conditions, pH below 7.0. Some of the
major constituents of organic compound found in humic acids are Amino Acids,
Pyramadines, Uronic acids, Purines, Methyl Suagrs, Amino Sugars, Pentose and
Hexose Sugars, Sugar Alcohol, and Aliphatic Acids.
Humic Acid contributes to plant growth and development by affecting the
physical, chemical, and biological properties of the soil. Any given benefit
of humus will vary from one soil to another and will depend upon environmental
conditions. Humic Acid benefits the physical condition of the soil in many
ways. Desirable soil structure, texture, and looseness are promoted,
specifically in tight clay soils. Good soil structure with humic acid can help
drainage, increase water holding capacity, and raise aeration. When added to
the soil, humic acid can act as a buffer by preventing rapid changes in acidity
or alkalinity. A more favorable medium for plant root systems is another
physical condition that benefits from humic acid.
Humic acid also affects numerous chemical properties in the soil. First, humus
serves as a source of nutrients. Humic acid helps chelate micronutrients,
increasing the plant uptake. Another chemical benefit of humic acid is
increased ion exchange capacity in the soil, which leads to better retention
and utilisation of minerals and soil nitrogen.
Biological conditions of the soil also benefit from humic acid. Humic acid aids
to increase activities of micro-flora and micro-faunal organisms. Plant
cellular growth and divisions can be accelerated due to the presence of auxin
type reactions with humic acid. Many investigators have also observed a
positive effect of humic substances on the growth of various groups of
microorganism. They attributed this to the presence of Iron in the humic acids
and their colloidal nature, or they regarded humic substances as organic
catalysts.
Humic Acid and Today’s Farming Industry
Modern day soils have been over-cropped, abused, and depleted of organic matter
and certain essential elements. Modern day agricultural practices greatly
increase the rate of the utilisation and destruction of humic material. Soil
humus is not a stable material. Any changes in natural conditions will result
in changes in humus content of the soil. Some of these changes are irrigation,
drainage, deforestation, annual removal of crops, and normal cultivation of
crops. All these changes lead to a rapid and marked change of the humus
balance of the affected soil.
The fertiliser industry now recognises the importance of maintaining the humic
content of soils as an aid to increased good productivity. Within recent years
many soil management programs have been designed to increase, or at least maintain,
the humic materials. The far-sighted grower is also beginning to change his
attitude toward the soil. He is faced with many ecological considerations as
he encounters today’s problems of pollution, presence of harmful chemicals in
treated grains and forage, and depletion of soil organic matter. Modern
cultivation practices greatly accelerate the destruction of humic material,
which must be replaced in some matter if the productivity of the soil is to be
maintained.